FR3113251A1 - Device for disinfection and/or sterilization of a gas in a conduit - Google Patents

Abstract

The present invention relates to a treatment device, for the disinfection and/or sterilization of a gas traveling in a conduit, comprising at least one radiating source (2), for the production of UV radiation, and a combination of mirrors (3 ), intended to reflect said UV radiation. Said combination of mirrors (3) comprises at least two side mirrors (4, 5) configured to reflect at least a part of said UV radiation in the form of directional beams (F1, F2) directed between said at least two side mirrors (4, 5) and crossing said passage (6) in both directions. And at least one of said two side mirrors (4, 5) consists of a reflector mirror (4) coupled to said at least one radiating source to produce a directional beam (F1, F2) oriented towards the other side mirror (4 , 5). Figure for abstract: 1

Description

Device for disinfection and/or sterilization of a gas in a conduit

Technical field of the invention

The present invention relates to the technical field of ultraviolet sterilization and/or disinfection.

It relates in particular to devices for the disinfection and/or sterilization of a gas in a conduit, in particular of the air traveling in a conduit.

State of the art

The ventilation of an interior space contributes to comfort and air quality by evacuating pollutants (odors, humidity, combustion products from heating appliances, microorganisms, etc.). It also contributes to preserving this interior space by avoiding disorders due to insufficient ventilation (condensation and development of mould).

The circulating air is however likely to contain pathogenic microorganisms (viruses, bacteria, etc.). These are then likely to be transported and disseminated in the ambient air of the interior space via the ventilation system.

This presence of microorganisms dangerous to health, transported by circulating air, may require taking the necessary measures to eradicate these pathogens.

One of the solutions consists in the implementation of a device for the disinfection and/or sterilization of the air circulating in the ducts.

Disinfection / sterilization by ultraviolet radiation (referred to as UV hereafter) is a response to this problem. The deactivation of the microorganisms is obtained by subjecting them to a sufficient dose of germicidal type UV radiation.

This dose corresponds to the cumulative radiation received by each microorganism during its stay in the irradiation zone. This dose is therefore directly proportional to the intensity of the radiation and the residence time in the radiation field.

However, the radiation from lamps is diffuse in all directions, thus generating radiation whose intensity decreases very rapidly with distance.

As a result, the devices usually used require the installation of a large number of individual lamps in the ducts so as to ensure sufficient irradiation efficiency. Such a configuration creates pressure drops, a great complexity of installation and maintenance; it also requires a detailed study of each location.

There is thus an interest in having devices for the disinfection and/or sterilization of a gas traveling in a duct, in particular of the air traveling in a duct, the effectiveness of which is improved.

Presentation of the invention

In order to remedy the aforementioned drawback of the state of the art, the present invention proposes a treatment device for the disinfection and/or sterilization of a gas (air for example) traveling in a conduit.

The processing device according to the invention comprises:

(i) at least one radiating source (also called “light source”), for the production of UV radiation, preferably UV-C radiation,

(ii) a combination of mirrors, associated with said at least one radiating source and intended to reflect said UV radiation.

The combination of mirrors comprises at least two side mirrors which are located on either side of a passage through which the gas to be treated is intended to flow.

Said at least two side mirrors are configured to reflect at least a portion of said UV radiation in the form of directional beams of UV radiation which are directed between said at least two side mirrors and which pass through said passage in both directions.

And at least one of said two side mirrors consists of a reflector mirror which is coupled to said at least one radiating source to produce a directional beam of UV radiation, advantageously a parallel directional beam, which is oriented towards another side mirror.

In the present invention, the passage is thus crossed, among other things, by a combination of directional beams of UV radiation, advantageously parallel, offering optimum efficiency for the deactivation of the microorganisms traveling through the passage.

This combination of mirrors offers optimum efficiency for said at least one radiating source.

Without being limited by any theory, said combination of mirrors offers optimum efficiency for said at least one radiating source, all the higher in the presence of parallel radiation (advantageously oriented perpendicular to the mirrors). In the presence of such parallel radiation, the radiation decreases little with the distance traveled, and thus it is advantageously reflected alternately from one mirror to the other, a large number of times, multiplying the efficiency of the radiation with each passage.

Preferably, the reflecting mirror has a concave profile, advantageously with a parabolic or semi-elliptical section.

The reflecting mirror advantageously comprises:

- a longitudinal opening facing the other side mirror, and/or

- An optical focal point coinciding with the center of said at least one radiating source.

Generally, said at least two side mirrors are configured to reflect at least a portion of said UV radiation in the form of two directional beams of UV radiation which are directed between said at least two side mirrors and which each cross said passage in one direction , inverse to each other.

According to a first preferred embodiment, the processing device comprises:

- two radiating sources, advantageously located on the same optical plane, on either side of said passage, and

- two side mirrors consisting of reflector mirrors, advantageously identical with respect to each other, which are each coupled to one of said radiating sources to each produce a directional beam of UV radiation, advantageously parallel, which is oriented towards the other side mirror, in the opposite direction relative to each other.

According to a second preferred embodiment, said processing device comprises:

- a radiant source,

- a first side mirror consisting of a reflector mirror which is coupled to said radiating source to produce a directional beam of UV radiation, advantageously parallel, which is oriented towards a second side mirror, and

- said second lateral mirror consisting of a plane mirror, located facing said first lateral mirror, to generate a directional beam of UV radiation which is reflected towards said first lateral mirror,

which plane mirror defines a general plane which is perpendicular to an optical plane of said first side mirror.

The width of the plane mirror is advantageously greater than or equal to the width of the longitudinal opening of the reflector mirror.

Yet according to another embodiment, said processing device comprises:

- a radiant source,

- a first side mirror consisting of a reflector mirror which is coupled to said radiating source to produce a directional beam of UV radiation, advantageously parallel, which is oriented towards a second side mirror,

- at least one additional first side mirror, located at least on one side of said first side mirror, advantageously on one side of said first side mirror or on either side of said first side mirror, and

- said second lateral mirror, located opposite said first lateral mirror, advantageously a flat central reflector mirror (case where said at least one additional first lateral mirror is located on one side of said first lateral mirror) or a central dihedral reflector mirror (case where said at least one first additional side mirror is located on either side of said first side mirror), to produce a directional beam of UV radiation, advantageously parallel, which is oriented towards at least one first additional side mirror,

- at least one second additional side mirror, located at least on one side of said second side mirror, advantageously on one side of said second side mirror or on either side of said second side mirror.

Said second side mirror, said at least one first additional side mirror and said at least one second additional side mirror are configured to reflect at least a portion of said UV radiation in the form of directional beams of UV radiation which are directed between said at least one first additional side mirror and said at least one second additional side mirror and which cross said passage in both directions, according to a zigzag trajectory.

Said at least one first additional lateral mirror and said at least one second additional lateral mirror are advantageously plane lateral mirrors, preferably in the form of simple parallel mirrors or in the form of dihedral mirrors.

Preferably, said processing device comprises a combination of mirrors chosen from:

(i) a first combination of mirrors comprising:

- said second lateral mirror, located facing said first lateral mirror, forming a central dihedral reflector mirror,

- first additional dihedral side mirrors, located on either side of said first side mirror, and

- second additional dihedral side mirrors, located on either side of said second side mirror,

Where

(ii) a second combination of mirrors comprising:

- said second lateral mirror, located facing said first lateral mirror, forming a central dihedral reflector mirror,

- first additional plane side mirrors, located on either side of said first side mirror, and

- second additional plane side mirrors, located on either side of said second side mirror,

Where

(iii) a third combination of mirrors comprising:

- said second lateral mirror, located facing said first lateral mirror, forming a central plane reflector mirror,

- first additional side mirrors, flat or dihedral, located on one side of said first side mirror, and

- additional second lateral mirrors, flat or dihedral, located on one side of said second lateral mirror.

Other non-limiting and advantageous characteristics of the first combination in accordance with the invention, taken individually or according to all the technically possible combinations, are the following:

- the first dihedral reflector mirrors and the second dihedral reflector mirrors advantageously comprise several juxtaposed dihedral mirrors;

- each dihedral mirror is arranged so that its bisector plane extends parallel to the optical plane of the first lateral mirror and to the bisector plane of the other dihedral mirrors; each plane reflector also extends parallel to the longitudinal axis passing through the center of the radiating source;

- the first dihedral reflector mirrors and the second dihedral reflector mirrors are identical with respect to each other;

- the first dihedral reflector mirrors and the second dihedral reflector mirrors are reversed on either side of the passage;

- Two adjoining dihedral mirrors of the second lateral mirror form a pair of primary planar reflectors, convex, which is located and centered facing the primary reflector mirror;

- the first dihedral reflector mirrors and/or the second dihedral reflector mirrors carry an end plane reflector which is provided to reflect the directional beam coming from an end plane reflector.

In general, said combination of mirrors also comprises at least one source mirror, concave profile with section in an arc of a circle, partially enveloping said radiating source.

The source mirror includes:

- a longitudinal opening, oriented towards the reflecting mirror, and

- an optical focal point, advantageously coinciding with the center of said radiating source and with the optical focal point of said reflecting mirror.

The source mirror advantageously extends over an angular sector of at least 170°, or even 175°, or even 180°.

The source mirror advantageously extends over an optical angular sector of the radiating source, advantageously complementary to that received from said reflector mirror.

Said at least one radiating source and said at least one source mirror are advantageously located, at least partially, in the size of the reflector mirror defined by a plane passing through its longitudinal opening.

Other non-limiting and advantageous characteristics of the product/process in accordance with the invention, taken individually or in all technically possible combinations, are the following:

- said combination of mirrors also comprises at least two transverse mirrors, parallel to each other and framing the side mirrors; these two transverse mirrors, in the presence of lamps and reflector mirrors with rectilinear generators, offer the advantage of returning the flat parallel beam towards the center of the passage, thus avoiding losses in the radiation plane:

- said at least one radiant source consists of at least one tubular UV-C lamp; preferably, the surface of said at least one radiating source is cylindrical and said at least one source mirror is adjacent to the surface of said at least one radiating source;

- said processing device advantageously comprises sensor means suitable for sensing the intensity of the radiation within the passage;

- said processing device comprises control means, suitable for controlling the power of said at least one radiant source and, preferably, which control means comprise at least one module chosen from among a control module suitable for adjusting the power said at least one radiant source taking into account a radiation intensity setpoint (also called "radiant intensity") and the radiation intensity collected by the sensor means and/or a control module adapted to adjust the power of said at least one radiant source taking into account the speed of the gas flow through said passage.

The present invention also relates to the ventilation system, for example for a room, a building or a machine, comprising at least one duct provided with a treatment device according to the invention.

The processing device forms a section of said duct or is attached to a section of said duct.

Of course, the different characteristics, variants and embodiments of the invention can be associated with each other in various combinations insofar as they are not incompatible or exclusive of each other.

Claims (14)

Treatment device, for the disinfection and/or sterilization of a gas traveling in a conduit, which treatment device (1) comprises:
(i) at least one radiant source (2), for the production of UV radiation, preferably UV-C radiation,
(ii) a combination of mirrors (3), associated with said at least one radiant source (2) and intended to reflect said UV radiation,
characterized in that said combination of mirrors (3) comprises at least two side mirrors (4, 5, 45, 46, 55, 58) which are located on either side of a passage (6) through which the gases to be treated are intended to circulate,
in that said at least two side mirrors (4, 5, 45, 46, 55, 58) are configured to reflect at least a part of said UV radiation in the form of directional beams (F1, F2, F3) of UV rays which are directed between said at least two side mirrors (4, 5, 45, 46, 55, 58) and which pass through said passage (6) in both directions, and
in that at least one of said at least two side mirrors (4, 5, 45, 46, 55, 58) consists of a reflector mirror (4) which is coupled to said at least one radiant source to produce a directional beam (F1, F2) of UV radiation, advantageously a parallel directional beam, which is directed towards another side mirror (4, 5). Processing device, according to Claim 1, characterized in that the said reflecting mirror (4) has a concave profile, advantageously with a parabolic or semi-elliptical section,
which reflecting mirror (4) advantageously comprises:
- a longitudinal opening (41) oriented towards the other side mirror (4, 5), and/or
- an optical focus (42) coinciding with the center (2') of said at least one radiating source (2). Treatment device, according to any one of Claims 1 or 2, characterized in that the said at least two lateral mirrors (4, 5, 45, 46, 55, 58) are configured to reflect at least a part of the said UV radiation under the form of two directional beams (F1, F2) of UV radiation which are directed between said at least two side mirrors (4, 5, 45, 46, 55, 58) and which each cross said passage (6) in one direction, inverse to each other. Processing device, according to claim 3, characterized in that said processing device (1) comprises:
- two radiating sources (2), advantageously located on the same optical plane (P), on either side of said passage (6), and
- two side mirrors (4) consisting of reflector mirrors, advantageously identical to each other, which are each coupled to one of said radiating sources (2) to each produce a directional beam (F1, F2) of UV radiation, advantageously parallel, which is oriented towards the other side mirror, in opposite directions relative to each other. Processing device, according to claim 3, characterized in that said processing device (1) comprises:
- a radiant source (2),
- a first side mirror (4) consisting of a reflector mirror (4) which is coupled to said radiating source (2) to produce a directional beam (F1) of UV radiation, advantageously parallel, which is oriented towards a second side mirror ( 5), and
- said second lateral mirror (5) consisting of a plane mirror (5), located facing said first lateral mirror (4), to generate a directional beam (F2) of UV radiation which is reflected towards said first lateral mirror (4) ,
which plane mirror (5) defines a general plane which is perpendicular to an optical plane (4') of said first side mirror (4). Processing device, according to any one of Claims 1 to 3, characterized in that the said processing device (1) comprises:
- a radiant source (2),
- a first side mirror (4) consisting of a reflector mirror (4) which is coupled to said radiating source (2) to produce a directional beam (F1) of UV radiation, advantageously parallel, which is oriented towards a second side mirror ( 5),
- at least one first additional lateral mirror (45, 46), advantageously flat, located at least on one side of said first lateral mirror (4), advantageously on either side of said first lateral mirror (4), and
- said second lateral mirror (5), located opposite said first lateral mirror (4), advantageously a central dihedral reflector mirror, to produce a directional beam (F2) of UV radiation, advantageously parallel, which is oriented towards at least a first additional side mirror (45, 46),
- at least one second additional lateral mirror (55, 58), advantageously plane, located at least on one side of said second lateral mirror (5), advantageously on either side of said second lateral mirror (5),
which second side mirror (5), which at least one additional first side mirror (45, 46) and which at least one additional second side mirror (55, 58) are configured to reflect at least a part of said UV radiation in the form of directional beams (F3) of UV radiation which are directed between said at least one first additional side mirror (45, 46) and said at least one second additional side mirror (55, 58) and which pass through said passage (6) in both direction, following a zigzag trajectory. Processing device, according to claim 6, characterized in that said processing device (1) comprises a combination of mirrors (3) chosen from:
(i) a first combination of mirrors (3) comprising:
- said second lateral mirror (5), located facing said first lateral mirror (4), forming a central dihedral reflector mirror (5),
- first additional side mirrors (45) dihedral, located on either side of said first side mirror (4), and
- second additional side mirrors (55) dihedral, located on either side of said second side mirror (5),
Where
(ii) a second combination of mirrors (3) comprising:
- said second lateral mirror (5), located facing said first lateral mirror (4), forming a central dihedral reflector mirror,
- first additional side mirrors (45) planes, located on either side of said first side mirror (4), and
- second additional side mirrors (58) planes, located on either side of said second side mirror (5),
Where
(iii) a third combination of mirrors comprising:
- said second lateral mirror (5), located opposite said first lateral mirror (4), forming a central plane reflector mirror,
- first additional lateral mirrors (45), flat or dihedral, located on one side of said first lateral mirror (4), and
- second additional side mirrors (55, 58), planes or dihedral, located on one side of said second side mirror (4). Processing device, according to any one of Claims 1 to 7, characterized in that the said combination of mirrors (3) further comprises at least one source mirror (8), concave profile with an arcuate section, partially enveloping the said source radiant (2),
which source mirror (8) comprises:
- a longitudinal opening (81), oriented towards the reflecting mirror (4), and
- an optical focus (82), advantageously coinciding with the center (2') of said radiating source (2) and with the optical focus (42) of said reflecting mirror (4). Processing device, according to any one of Claims 1 to 8, characterized in that the said at least one radiating source (2), and where appropriate the said at least one source mirror (8), are implanted, at least partially, within the size of the reflecting mirror (4) defined by a plane passing through its longitudinal opening (41). Processing device, according to any one of Claims 1 to 9, characterized in that the said combination of mirrors (3) further comprises at least two transverse mirrors (9), advantageously parallel with respect to each other, framing the side mirrors (4, 5). Treatment device, according to any one of Claims 1 to 10, characterized in that the said at least one radiating source (2) consists of at least one tubular UV-C lamp. Treatment device, according to any one of Claims 1 to 11, characterized in that the said treatment device (1) comprises sensor means (11) adapted to detect the intensity of radiation within the passage (6). Processing device, according to any one of Claims 1 to 12, characterized in that the said processing device (1) comprises control means (10), suitable for controlling the power of the said at least one radiating source ( 2),
and, preferably, which control means (10) comprise at least one module chosen from:
- in combination with claim 9, a control module (101) adapted to adjust the power of said at least one radiant source (2) taking into account a radiation intensity setpoint and the radiation intensity collected by the sensor means (11),
- a control module (102) adapted to adjust the power of said at least one radiant source (2) taking into account the speed of the flow of gases through said passage (6). Ventilation system, for example for a room, a building or a machine, comprising at least one duct provided with a treatment device (1) according to any one of Claims 1 to 13,
which processing device (1) forms a section of said pipe or is attached to a section of said pipe.